Your search keyword '"Shubina TV"' showing total 20 results

1. Non-stoichiometry and non-homogeneity in InN

Author

Scott, K, Butcher, A, Wintrebert-Fouquet, M, Chen, PPT, Prince, KE, Timmers, H, Shrestha, SK, Shubina, TV, Ivanov, SV, Wuhrer, R, Phillips, MR, and Monemar, B

Abstract

It is shown that the wide variation of apparent band-gap observed for thin films nominally referred to as InN is strongly influenced by variations in the nitrogen:indium stoichiometry. InN samples grown by remote plasma enhanced chemical vapour deposition show a change in band-gap between 1.8 and 1.0 eV that is not due to the Moss-Burstein effect, oxygen inclusion or quantum size effects, but for which changes in the growth temperature result in a strong change in stoichiometry. Material non-homogenity and non-stoichiometry appear to be general problems for InN growth. Excess nitrogen can be present at very high levels and indium rich material is also found. This work shows that the extent of the Moss-Burstein effect will have to be reassessed for InN. © 2005 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Published

2005

2. Polarized microphotoluminescence and reflectance spectroscopy of GaN with k perpendicular to c : Strongly pi-polarized line near the A exciton

Author

Shubina, TV, Paskova, Tanja, Toropov, AA, Ivanov, SV, Monemar, Bo, Shubina, TV, Paskova, Tanja, Toropov, AA, Ivanov, SV, and Monemar, Bo

Abstract

Polarized microphotoluminescence (mu-PL) and reflectivity studies of thick wurtzite GaN grown by hydride vapor phase epitaxy on c sapphire are performed with the light vector k both normal to the c axis (kperpendicular toc) and parallel to it. A strong PL peak is found in the vicinity of the A exciton in pi polarization (kperpendicular toc, E parallel to the c axis). in apparent contradiction to the selection rules. The pi-polarized component exceeds in intensity the sigma-polarized one up to similar to50 K. Power- and temperature-dependent measurements of both no-phonon and longitudinal optical phonon-assisted (monitoring the real density of exciton states) mu-PL reveal the complex nature of the pi-polarized PL line near the A exciton. At low temperatures the pi-component involves a bound B exciton contribution, while at higher temperatures contributions of scattered A exciton states become appreciable, The enhancement of the pi-polarized component is attributed to the complex structure of the exciton-polariton branches for kperpendicular toc. Temperature-dependent mu-PL and reflectance spectroscopies reveal additionally a difference in the optical properties between the sample regions at the top surface and the cleaved edges, tentatively explained as induced by different strains in these regions.

Published

2002

3. Direct observation of split-mode exciton-polaritons in a single MoS 2 nanotube.

Author

Galimov AI, Kazanov DR, Poshakinskiy AV, Rakhlin MV, Eliseyev IA, Toropov AA, Remškar M, and Shubina TV

Abstract

A single nanotube synthesized from a transition metal dichalcogenide (TMDC) exhibits strong exciton resonances and, in addition, can support optical whispering gallery modes. This combination is promising for observing exciton-polaritons without an external cavity. However, traditional energy-momentum-resolved detection methods are unsuitable for this tiny object. Instead, we propose to use split optical modes in a twisted nanotube with the flattened cross-section, where a gradually decreasing gap between the opposite walls leads to a change in mode energy, similar to the effect of the barrier width on the eigenenergies in the double-well potential. Using micro-reflectance spectroscopy, we investigated the rich pattern of polariton branches in single MoS 2 tubes with both variable and constant gaps. Observed Rabi splitting in the 40-60 meV range is comparable to that for a MoS 2 monolayer in a microcavity. Our results, based on the polariton dispersion measurements and polariton dynamics analysis, present a single TMDC nanotube as a perfect polaritonic structure for nanophotonics.

Published

2024

4. Quantum Dot Photoluminescence Enhancement in GaAs Nanopillar Oligomers Driven by Collective Magnetic Modes.

Author

Kroychuk MK, Shorokhov AS, Yagudin DF, Rakhlin MV, Klimko GV, Toropov AA, Shubina TV, and Fedyanin AA

Abstract

Single photon sources based on semiconductor quantum dots are one of the most prospective elements for optical quantum computing and cryptography. Such systems are often based on Bragg resonators, which provide several ways to control the emission of quantum dots. However, the fabrication of periodic structures with many thin layers is difficult. On the other hand, the coupling of single-photon sources with resonant nanoclusters made of high-index dielectric materials is known as a promising way for emission control. Our experiments and calculations show that the excitation of magnetic Mie-type resonance by linearly polarized light in a GaAs nanopillar oligomer with embedded InAs quantum dots leads to quantum emitters absorption efficiency enhancement. Moreover, the nanoresonator at the wavelength of magnetic dipole resonance also acts as a nanoantenna for a generated signal, allowing control over its radiation spatial profile. We experimentally demonstrated an order of magnitude emission enhancement and numerically reached forty times gain in comparison with unstructured film. These findings highlight the potential of quantum dots coupling with Mie-resonant oligomers collective modes for nanoscale single-photon sources development.

Published

2023

5. A Comparative Study of the Band-Edge Exciton Fine Structure in Zinc Blende and Wurtzite CdSe Nanocrystals.

Author

Golovatenko AA, Kalitukha IV, Dimitriev GS, Sapega VF, Rakhlin MV, Galimov AI, Shubina TV, Shornikova EV, Qiang G, Yakovlev DR, Bayer M, Biermann A, Hoffmann A, Aubert T, Hens Z, and Rodina AV

Abstract

In this paper, we studied the role of the crystal structure in spheroidal CdSe nanocrystals on the band-edge exciton fine structure. Ensembles of zinc blende and wurtzite CdSe nanocrystals are investigated experimentally by two optical techniques: fluorescence line narrowing (FLN) and time-resolved photoluminescence. We argue that the zero-phonon line evaluated by the FLN technique gives the ensemble-averaged energy splitting between the lowest bright and dark exciton states, while the activation energy from the temperature-dependent photoluminescence decay is smaller and corresponds to the energy of an acoustic phonon. The energy splittings between the bright and dark exciton states determined using the FLN technique are found to be the same for zinc blende and wurtzite CdSe nanocrystals. Within the effective mass approximation, we develop a theoretical model considering the following factors: (i) influence of the nanocrystal shape on the bright-dark exciton splitting and the oscillator strength of the bright exciton, and (ii) shape dispersion in the ensemble of the nanocrystals. We show that these two factors result in similar calculated zero-phonon lines in zinc blende and wurtzite CdSe nanocrystals. The account of the nanocrystals shape dispersion allows us to evaluate the linewidth of the zero-phonon line.

Published

2022

6. MoS 2 flake as a van der Waals homostructure: luminescence properties and optical anisotropy.

Author

Kotova LV, Rakhlin MV, Galimov AI, Eliseyev IA, Borodin BR, Platonov AV, Kirilenko DA, Poshakinskiy AV, and Shubina TV

Abstract

We investigated multilayer plates prepared by exfoliation from a high-quality MoS 2 crystal and revealed that they represent a new object - a van der Waals homostructure consisting of a bulk core and a few detached monolayers on its surface. This architecture comprising elements with different electron band structures leads to specific luminescence, when the broad emission band from the core is cut by the absorption peaks of strong exciton resonances in the surface monolayers. The exfoliated flakes exhibit strong optical anisotropy. We have observed linear to circular polarization conversion that reaches 15% for normally incident light in transmission geometry. This background effect is due to the fluctuations of the c axis relative to the normal, whereas the pronounced resonance contribution is explained by the polarization anisotropy of the excitons localized in the stripes of the dissected surface monolayers.

Published

2021

7. State-of-the-art and prospects for intense red radiation from core-shell InGaN/GaN nanorods.

Author

Evropeitsev EA, Kazanov DR, Robin Y, Smirnov AN, Eliseyev IA, Davydov VY, Toropov AA, Nitta S, Shubina TV, and Amano H

Abstract

Core-shell nanorods (NRs) with InGaN/GaN quantum wells (QWs) are promising for monolithic white light-emitting diodes and multi-color displays. Such applications, however, are still a challenge because intensity of the red band is too weak compared with blue and green. To clarify this problem, we measured photoluminescence of different NRs, depending on power and temperature, as well as with time resolution. These studies have shown that dominant emission bands come from nonpolar and semipolar QWs, while a broad yellow-red band arises mainly from defects in the GaN core. An emission from polar QWs located at the NR tip is indistinguishable against the background of defect-related luminescence. Our calculations of electromagnetic field distribution inside the NRs show a low density of photon states at the tip, which additionally suppresses the radiation of polar QWs. We propose placing polar QWs inside a cylindrical part of the core, where the density of photon states is higher and the well area is much larger. Such a hybrid design, in which the excess of blue radiation from shell QWs is converted to red radiation in core wells, can help solve the urgent problem of red light for many applications of NRs.

Published

2020

8. Strongly Confined Excitons in GaN/AlN Nanostructures with Atomically Thin GaN Layers for Efficient Light Emission in Deep-Ultraviolet.

Author

Toropov AA, Evropeitsev EA, Nestoklon MO, Smirnov DS, Shubina TV, Kaibyshev VK, Budkin GV, Jmerik VN, Nechaev DV, Rouvimov S, Ivanov SV, and Gil B

Abstract

Fascinating optical properties governed by extremely confined excitons have been so far observed in 2D crystals like monolayers of transition metal dichalcogenides. These materials, however, are limited for production by epitaxial methods. Besides, they are not suitable for the development of optoelectronics for the challenging deep-ultraviolet spectral range. Here, we present a single monolayer of GaN in AlN as a heterostructure fabricated by molecular beam epitaxy, which provides extreme 2D confinement of excitons, being ideally suited for light generation in the deep-ultraviolet. Optical studies in the samples, supplemented by a group-theory analysis and first-principle calculations, make evident a giant enhancement of the splitting between the dark and bright excitons due to short-range electron-hole exchange interaction that is a fingerprint of the strongly confined excitons. The practical significance of our results is in the observation of the internal quantum yield of the room-temperature excitonic emission as high as ∼75% at 235 nm.

Published

2020

9. Many-particle excitations in non-covalently doped single-walled carbon nanotubes.

Author

Eremin TV, Obraztsov PA, Velikanov VA, Shubina TV, and Obraztsova ED

Abstract

Doping of single-walled carbon nanotubes leads to the formation of new energy levels which are able to participate in optical processes. Here, we investigate (6,5)-single walled carbon nanotubes doped in a solution of hydrochloric acid using optical absorption, photoluminescence, and pump-probe transient absorption techniques. We find that, beyond a certain level of doping, the optical spectra of such nanotubes exhibit the spectral features related to two doping-induced levels, which we assign to a localized exciton [Formula: see text] and a trion T, appearing in addition to an ordinary exciton [Formula: see text]. We evaluate the formation and relaxation kinetics of respective states and demonstrate that the kinetics difference between E 1 and X energy levels perfectly matches the kinetics of the state T. This original finding evidences the formation of trions through nonradiative relaxation via the [Formula: see text] level, rather than via a direct optical excitation from the ground energy state of nanotubes.

Published

2019

10. InSe as a case between 3D and 2D layered crystals for excitons.

Author

Shubina TV, Desrat W, Moret M, Tiberj A, Briot O, Davydov VY, Platonov AV, Semina MA, and Gil B

Abstract

InSe is a promising material in many aspects where the role of excitons is decisive. Here we report the sequential appearance in its luminescence of the exciton, the biexciton, and the P-band of the exciton-exciton scattering while the excitation power increases. The strict energy and momentum conservation rules of the P-band are used to reexamine the exciton binding energy. The new value ≥20 meV is markedly higher than the currently accepted one (14 meV), being however well consistent with the robustness of the excitons up to room temperature. A peak controlled by the Sommerfeld factor is found near the bandgap (~1.36 eV). Our findings supported by theoretical calculations taking into account the anisotropic material parameters question the pure three-dimensional character of the exciton in InSe, assumed up to now. The refined character and parameters of the exciton are of paramount importance for the successful application of InSe in nanophotonics.

Published

2019

11. Localization and transient emission properties in InGaN/GaN quantum wells of different polarities within core-shell nanorods.

Author

Robin Y, Evropeitsev EA, Shubina TV, Kirilenko DA, Davydov VY, Smirnov AN, Toropov AA, Eliseyev IA, Bae SY, Kushimoto M, Nitta S, Ivanov SV, and Amano H

Abstract

Transient photoluminescence (PL) characteristics and localization phenomena in InGaN/GaN core-shell nanorods (NRs) were investigated from 6 K up to 285 K. The NRs exhibit three well-defined PL bands in the near-UV, blue, and green range ascribed to the emission of quantum well (QW) areas situated at the (1.00) sidewalls, (10.1) top facets, and (00.1) tip, respectively. At low temperature, time-resolved PL shows a fast decay time of about 0.5 ns for the semi- and non-polar QWs, while the polar QWs exhibit at least a twice-longer time. Rapid delocalization of carriers above 50 K indicates shallow potential fluctuations in the QWs. At room temperature, the characteristic fast PL decay time of the three QW bands stabilizes around 300 ps. The slow decaying PL components have different characteristic decay times that are explained by additional localization at basal stacking faults (BSFs), taking into account the quantum confined Stark effect. In addition, narrow excitonic luminescence lines are observed in the BSF-enriched polar QWs, providing direct evidence of the impact of the BSF/QW crossings on the optical properties of the NRs. A PL rise time of about 100 ps does not show any deviation between bands. These findings are suggestive of similar transport mechanisms in temperature equilibrium without inter-facet transport between different QWs. We believe that predictable transient characteristics can play a key role in creating uniform NR ensembles for device applications.

Published

2018

12. Enhanced excitonic emission efficiency in porous GaN.

Author

Ngo TH, Gil B, Shubina TV, Damilano B, Vezian S, Valvin P, and Massies J

Abstract

We investigate the optical properties of porous GaN films of different porosities, focusing on the behaviors of the excitonic features in time-integrated and time-resolved photoluminescence. A substantial enhancement of both excitonic emission intensity and recombination rate, along with insignificant intensity weakening under temperature rise, is observed in the porous GaN films. These observations are in line with (i) the local concentration of electric field at GaN nanoparticles and pores due to the depolarization effect, (ii) the efficient light extraction from the nanoparticles. Besides, the porosification enlarges the surface of the air/semiconductor interface, which further promotes the extraction efficiency and suppresses non-radiative recombination channels. Our findings open a way to increasing the emission efficiency of nanophotonic devices based on porous GaN.

Published

2018

13. Insight into the performance of multi-color InGaN/GaN nanorod light emitting diodes.

Author

Robin Y, Bae SY, Shubina TV, Pristovsek M, Evropeitsev EA, Kirilenko DA, Davydov VY, Smirnov AN, Toropov AA, Jmerik VN, Kushimoto M, Nitta S, Ivanov SV, and Amano H

Abstract

We report on the thorough investigation of light emitting diodes (LEDs) made of core-shell nanorods (NRs) with InGaN/GaN quantum wells (QWs) in the outer shell, which are grown on patterned substrates by metal-organic vapor phase epitaxy. The multi-bands emission of the LEDs covers nearly the whole visible region, including UV, blue, green, and orange ranges. The intensity of each emission is strongly dependent on the current density, however the LEDs demonstrate a rather low color saturation. Based on transmission electron microscopy data and comparing them with electroluminescence and photoluminescence spectra measured at different excitation powers and temperatures, we could identify the spatial origination of each of the emission bands. We show that their wavelengths and intensities are governed by different thicknesses of the QWs grown on different crystal facets of the NRs as well as corresponding polarization-induced electric fields. Also the InGaN incorporation strongly varies along the NRs, increasing at their tips and corners, which provides the red shift of emission. With increasing the current, the different QW regions are activated successively from the NR tips to the side-walls, resulting in different LED colors. Our findings can be used as a guideline to design effectively emitting multi-color NR-LEDs.

Published

2018

14. InAs/AlGaAs quantum dots for single-photon emission in a red spectral range.

Author

Rakhlin MV, Belyaev KG, Klimko GV, Mukhin IS, Kirilenko DA, Shubina TV, Ivanov SV, and Toropov AA

Abstract

We report on comparative optical studies of InAs/Al 0.44 Ga 0.56 As quantum dots (QDs) grown by molecular beam epitaxy either with or without a thin GaAs interlayer inserted between the AlGaAs barrier and InAs QDs. Emission properties of individual QDs are investigated by micro-photoluminescence spectroscopy using 500-nm-size etched cylindric mesa structures. The single-photon statistics of the QDs of both types, emitting in the red spectral range between 636 and 750 nm, is confirmed by the measurements of the second-order correlation function. A negligibly small exciton fine structure splitting is detected in the majority of the QDs grown with the GaAs interlayer that implies the possibility of generating pairs of entangled photons with high entanglement fidelity.

Published

2018

15. III-nitride tunable cup-cavities supporting quasi whispering gallery modes from ultraviolet to infrared.

Author

Shubina TV, Pozina G, Jmerik VN, Davydov VY, Hemmingsson C, Andrianov AV, Kazanov DR, and Ivanov SV

Abstract

Rapidly developing nanophotonics needs microresonators for different spectral ranges, formed by chip-compatible technologies. In addition, the tunable ones are much in demand. Here, we present site-controlled III-nitride monocrystal cup-cavities grown by molecular beam epitaxy. The cup-cavities can operate from ultraviolet to near-infrared, supporting quasi whispering gallery modes up to room temperature. Besides, their energies are identical in large 'ripened' crystals. In these cavities, the refractive index variation near an absorption edge causes the remarkable effect of mode switching, which is accompanied by the spatial redistribution of electric field intensity with concentration of light into a subwavelength volume. Our results shed light on the mode behavior in semiconductor cavities and open the way for single-growth-run manufacturing the devices comprising an active region and a cavity with tunable mode frequencies.

Published

2015

16. Optically enhanced emission of localized excitons in InxGa1-xN films by coupling to plasmons in a gold nanoparticle.

Author

Toropov AA, Shubina TV, Jmerik VN, Ivanov SV, Ogawa Y, and Minami F

Abstract

We report on strong site-selective enhancement of the emission of localized excitons in an InxGa1-xN film, induced by resonant coupling to a single plasmon confined in a gold nanoparticle. The particle was attached to an atomic-force-microscope probe and placed at the near-field distance of the surface. The observation is explained by the enhancement of the spontaneous emission recombination rate of the excitons due to the local increase in the photonic mode density near the metal particle. The interpretation is consistent with the intensity increase and lifetime shortening of the emission observed in the same film with deposited Au clusters. We show that the nanoscale roughness of the film is an important prerequisite of the efficient plasmonic enhancement.

Published

2009

17. Resonant light delay in GaN with ballistic and diffusive propagation.

Author

Shubina TV, Glazov MM, Toropov AA, Gippius NA, Vasson A, Leymarie J, Kavokin A, Usui A, Bergman JP, Pozina G, and Monemar B

Abstract

We report on a strong delay in light propagation through bulk GaN, detected by time-of-flight spectroscopy. The delay increases resonantly as the photon energy approaches the energy of a neutral-donor bound exciton (BX), resulting in a velocity of light as low as 2100 km/s. In the close vicinity of the BX resonance, the transmitted light contains both ballistic and diffusive components. This phenomenon is quantitatively explained in terms of optical dispersion in a medium where resonant light scattering by the BX resonance takes place in addition to the polariton propagation.

Published

2008

18. Mie resonances, infrared emission, and the band gap of InN.

Author

Shubina TV, Ivanov SV, Jmerik VN, Solnyshkov DD, Vekshin VA, Kop'ev PS, Vasson A, Leymarie J, Kavokin A, Amano H, Shimono K, Kasic A, and Monemar B

Abstract

Mie resonances due to scattering or absorption of light in InN-containing clusters of metallic In may have been erroneously interpreted as the infrared band gap absorption in tens of papers. Here we show by direct thermally detected optical absorption measurements that the true band gap of InN is markedly wider than the currently accepted 0.7 eV. Microcathodoluminescence studies complemented by the imaging of metallic In have shown that bright infrared emission at 0.7-0.8 eV arises in a close vicinity of In inclusions and is likely associated with surface states at the metal/InN interfaces.

Published

2004

19. [Thermodynamic interpretation of the nitrogen status of forest gray soil agrocenoses].

Author

Zykina GK and Shubina TV

Subjects

Agriculture, Hydrogen-Ion Concentration, Oxidation-Reduction, Thermodynamics, Nitrogen metabolism, Soil, Trees

Abstract

Thermodynamic approaches used in soil agrochemical studies allow to determine the direction of processes occurring in soils and to provide theoretically meaningful predictions of changes in ecosystems as a whole in response to various factors. Analysis of redox reactions of the NH4+ reversible NO3- equilibrium in agrocenoses of gray forest soil has shown that the additional introduction of nitrogen fertilizers is undesirable both from the economical and ecological points of view, since the dominating process occurring with the loss of nitrogen from the soil in the form of gaseous compounds is thermodynamically most preferred.

Published

2000

20. Resonant coupling of electrons and excitons in an aperiodic superlattice under electric fields studied by photoluminescence spectroscopy.

Author

Cao SM, Willander M, Toropov AA, Shubina TV, Mel'tser BY, Shaposhnikov SV, Kop'ev PS, Holtz PO, Bergman JP, and Monemar B

Published

1995